Proton Affinities of Primary Alkanols: An Appraisal ... - ACS Publications

John L. Holmes,* Christiane Aubry, and Paul M. Mayer. Department of Chemistry, UniVersity of Ottawa, 10 Marie-Curie, Ottawa, Ontario K1N 6N5, Canada...
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J. Phys. Chem. A 1999, 103, 705-709

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Proton Affinities of Primary Alkanols: An Appraisal of the Kinetic Method John L. Holmes,* Christiane Aubry, and Paul M. Mayer Department of Chemistry, UniVersity of Ottawa, 10 Marie-Curie, Ottawa, Ontario K1N 6N5, Canada ReceiVed: October 20, 1998; In Final Form: December 17, 1998

The kinetic method is a now well-established technique for determining thermochemical properties such as acidities and proton affinities. We present here a study of the application of the kinetic method to the proton affinities (PA) of a series of homologous primary alkanols, namely ethanol through n-octanol. Both metastable and collisionally activated dissociations of proton-bound alkanol pairs were studied, the latter as a function of the target gas and its pressure. Plots of ln([R1OH2+]/[R2OH2+]) vs PA for both experiments were obtained to determine new PA values and investigate the significance of the “effective temperature” term. When the experiments are considered in detail, it is apparent that the kinetic method is essentially a semiempirical relationship, without a sound physicochemical basis.

() ( )

E2° - E1° k1 Q1‡ ln ) ln ‡ + k2 RT Q2

Introduction The kinetic method introduced by Cooks1 has provided an alternative to equilibrium measurements2 and reaction bracketing experiments3 for measuring thermochemical properties. This method has been widely used for the determination of gas-phase acidities, basicities, and proton affinities of organic compounds as well as the determination of affinities for ions other than the proton.1c For proton affinities (PA) to be evaluated, proton-bound dimers, [B1-H-B2]+, are generated and isolated in a mass spectrometer, and the competitive reactions (a) and (b) yielding the individual protonated monomers are investigated. +

+

[B1-H-B2] f B1H + B2

(a)

[B1-H-B2]+ f B2H+ + B1

(b)

Upon fragmentation, the monomer having the greater proton affinity will preferentially carry the proton. The reactions are observed as metastable dissociations or induced by collisional excitation. Canonical transition state theory4 (which applies to species at an equilibrium thermodynamic temperature) has been applied to these systems.1 The rate constant for a reaction of such a species is given by the statistical thermodynamics version of the Arrhenius equation:

( )

ln k ) ln

Q‡ E° + Q RT

(1)

where Q and Q‡ are the partition functions for the reactant and the transition state, respectively, E° is the activation energy, R is the ideal gas constant, and T is the temperature. When there are two competing dissociations, their respective rate constants, k1 and k2, are given by * Corresponding author. e-mail: [email protected].

(2)

In the kinetic method, k1 and k2 are replaced by the respective product ion intensities [B1H+] and [B2H+], and eq 2 is simplified to permit the evaluation of the difference in proton affinities, E2° - E1° ) PA2 - PA1:

ln

[B1H+] [B2H+]

1 ∆PA ) (PA2 - PA1) ) RTeff RTeff

(3)

For eq 3 to apply, several assumptions are made. The most important is that the proton-bound molecular pairs have internal energy distributions that can be described by an “effective temperature” term, Teff. Note that, in general, a system of isolated ions generated in a mass spectrometer cannot be assumed to have a Boltzmann distribution of internal energies, except where special efforts are made to generate thermal equilibria, such as in high-pressure mass spectrometry.5 Also, the logarithm term should represent the ratio of the fractions of ions fragmenting that have internal energies from E1° f ∞ and from E2° f ∞, respectively. This presents a problem when studying the dissociation of metastable ions in a sector mass spectrometer, a point which will be discussed in detail later. The third assumption is that neither dissociation involves a reverse energy barrier. This is a priori likely when only simple bond cleavages are involved. Finally, it is assumed that there are no entropic effects, i.e., Q1‡ ) Q2‡. To use the simplified eq 3 to obtain an absolute proton affinity value, a reference base of known PA is required. For a series of molecules having a common functionality, it has been found that a plot of ln([B1H+]/[ B2H+]) vs ∆PA yields a straight line. Thus, from the slope of the plot, a temperaturelike term, Teff, can be obtained. It is a common belief that this parameter relates to the average internal energy of the ion population.1 If the ion population is not in thermal equilibrium with its surroundings, such as in an ion beam experiment or in partial thermal equilibrium, as in the case of high-pressure

10.1021/jp984094z CCC: $18.00 © 1999 American Chemical Society Published on Web 01/23/1999

706 J. Phys. Chem. A, Vol. 103, No. 6, 1999 experiments, the physical interpretation of the parameter obtained from the slope of the plot can be neither straightforward nor certain. A recent report by McMahon et al.6 describes a study of alkyl nitrile PA values by high-pressure mass spectrometry (equilibrium measurements, ∆G values) and the above kinetic method in which inter alia the “effective temperature” question was directly addressed. It was concluded that in these experiments the ion source temperature may be related to the “effective temperature”, but the inverse dependence observed could not readily be explained. In the interim, we have found evidence that the nitrile adduct ions in McMahon’s work were not metastable but were dissociating as a result of collisional excitation.7 Surprisingly few small heteroatom-containing homologous molecular series other than some amines have been investigated by this method for evaluating proton affinities.1b,c The present work was undertaken to discover whether the kinetic method is appropriate for the dissociation of proton-bound alkanols, (R1OH)H+(R2OH) (for which some reliable PA values exist), to compare the method for metastable and collisionally activated ions, and to explore the significance of the “effective temperature”. Experimental Procedures The proton-bound dimers were generated under CI conditions in the ion source of our modified triple-focusing (BEE) VG ZAB-2F mass spectrometer8 by self-protonation of the monomers. The metastable and collision-induced dissociations9 (MI and CID, respectively) of the mass-selected proton-bound dimers were studied in the second and third field-free regions of the instrument. Peak heights from individual scans were used to measure the relative abundances of the fragment ions. The ion source pressure was measured externally using an ion gauge. The ion source temperature was normally maintained at 423 ( 5 K, and the inlet system was kept at a similar temperature. The compounds were purchased from Aldrich Chemical Co. (Milwaukee, WI) and used without further purification. Results and Discussion Dissociation Characteristics of Metastable Ions. Preliminary experiments with a wide range of primary, secondary, and tertiary alkanols showed that for the latter two classes of compounds the metastable ion (MI) mass spectra for (R1OH)H+(R2OH) were often dominated by processes other than the dissociation to R1OH2+ and R2OH2+ (mainly olefin eliminations). The primary alkanols are not so disposed, and the competing reactions (a) and (b) provided the major signals in the MI mass spectra. However, the MI mass spectra of the higher homologues also showed a weak (